KR20000059346A - Injection method of pump housing and device thereof - Google Patents

Abstract

PURPOSE: A method and an apparatus are provided to reduce manufacturing cost and allow the manufacturing process to be performed with ease while performing an injection molding in two-stages. CONSTITUTION: A method comprises a first injection molding step for injecting half piece of the pump housing, and a second injection molding step of coupling the half piece of the pump housing by male and female snap fit(105), inserting and fitting a mold for supporting the lower portion of the pump housing at a state where each piece of pump housing is not escaped from each other with the assist of a convex portion formed at an edge, inserting and fixing a droop prevention device into an inlet(101), and performing an injection molding process. The droop prevention device comprises a supporting member for supporting the inlet, a fixing member for fixing the supporting member into the inlet, and a hinge for coupling the supporting member and the fixing member.

Description

Injection method of pump housing and apparatus used therein {INJECTION METHOD OF PUMP HOUSING AND DEVICE THEREOF}

The present invention relates to an injection method and a device of the pump housing, in particular, in the first injection injection and coupling a pair of pump housings are divided so as to cross the inlet and outlet vertically to be coupled by a snap fit, In the second injection, the present invention relates to an injection method of a pump housing and an apparatus used therefor that allow injection after inserting a deflection prevention device into an inlet.

In general, the pump housing is manufactured by injection. In this injection, a mold casting having a low melting point is manufactured and then instantaneously injected using the mold, and before the mold reaches the melting point due to the high temperature of the injection molding. Cool the injection molding.

After the injection is sufficiently cooled, the temperature of the mold is gradually raised, and when the temperature of the mold reaches the melting point, the pump housing is manufactured by maintaining the temperature to gradually melt the mold and separating the molten mold from the injection.

In addition, such a prior art uses a mold made of an alloy of lead and bismuth having a melting point of about 200 ° C. in a method called lost core used in Germany, and the melting point of the injection molding is about 220 ° C. It is produced using a material having a melting point.

However, a large cost is required to manufacture such a mold, and a separate production cost is required to produce a material having an appropriate melting point, and a waste of material is generated because a mold that does not have a set melting point cannot be used. It was. In addition, without this technical know-how, there was a problem that a considerable difficulty in manufacturing the mold.

Accordingly, an object of the present invention is to solve the above-mentioned shortcomings, and to inject and combine a pair of pump housings divided vertically across the inlet and outlet so as to be coupled by the snap fit in the first injection, and to the second injection. An object of the present invention is to provide an injection method of a pump housing and an apparatus used therefor that allow the injection of a deflection prevention device into an inlet and then an injection.

A feature of the present invention for achieving the above object is that a pair of snap fits are formed on the upper side of the pair of pump housings, respectively, and the pair of pump housings may be coupled to each other by a snap fit on the edges in contact with each other. A first injection step of injecting each half of the pump housing in which the unevenness is formed so as not to deviate from each other along the edges in contact with each other; And the pump housing is coupled by the respective female and male snap feet formed where the upper surface of the inlet and the upper surface of the inlet contact each other, and the pump housings are not separated from each other by the unevenness formed at the opposite edges of the pump housing. In the lower part of the pump housing to insert and fix the mold for supporting the inner side having a shape corresponding to the inner shape of the pump housing, and inserting and fixing the deflection prevention device to support to the inner upper surface of the inlet 2 and ejecting again A pump housing injection method comprising a secondary injection step, and an upper surface having a curved surface corresponding to an inner upper surface of the inlet of the pump housing, the support having a length such that an end end is in contact with the upper side of the mold; A fitting fixed to the inlet of the inlet to prevent the shape deformation of the inlet, and to fix the support in close contact with the inlet; And a hinge configured to rotatably couple the support and the fixing stand to be inserted into the inlet of the pump housing before the second injection to prevent the shape of the pump housing from being deformed by the pressure generated during the injection. It is in the deflection prevention device used in the

Figure 1a is a cross-sectional view of the pump housing of one side injected primarily by the present invention,

Figure 1b is a cross-sectional view showing the pump housing of the other side injected primarily by the present invention,

2 is a plan view showing the assembled state of the pump housing injected primarily;

3 is a view schematically showing a support inserted into the pump housing to prevent sag in the second injection,

4 is a view showing a state in which the support of Figure 3 is inserted and mounted.

* Explanation of symbols on the main parts of the drawings *

100 ... pump housing 101 ... inlet

102 ... outlet 103 ... unevenness

104 ... Euroguide 105 ... Snap Fit

200 ... deflection prevention device 201 ... support

202 ... Hinge 203 ... Fixture

210 ... mold

As shown in FIGS. 1A and 1B, an injection method of a pump housing according to the present invention primarily ejects a pair of pump housings 100 which are divided to be symmetrical with each other about an inlet 101 and an outlet 102. .

A pair of snap fits 105 are formed on the upper one side of the pair of pump housings 100 which are injected as described above, and a pair of snap fits 105 are formed at the edge where the pair of pump housings 100 are in contact with each other. When combined with each other by the concave-convex 103 is formed so as not to shift each other along the edges in contact with each other.

Since the pair of pump housings 100 are injected in half, respectively, it is easy to form the inlet 101 formed by the flow path guide 104 as shown in FIGS. 1A and 1B, and also the injection molded product from the mold after injection. It is easy to separate.

And the pump housing 100 is injected by the present invention is coupled by each of the female, male snap feet 105 formed where the upper surface of the outlet 102 and the upper surface of the inlet 101, the snap fit The pump housing 100 enters the secondary injection in a state where the pump housings 100 are not separated from each other by the unevenness 103 formed at the edge of the pump housing 100 which is coupled and contacted by the 105.

In the second injection, the pump housing 100 formed by the primary injection and coupled to the snap fit 105 serves as a mold as the pump housing 100 itself.

However, since the pump housing 100 itself cannot withstand the pressure of the melt injected in the injection, a mold 210 for supporting the inner side at the bottom of the pump housing 100 is required, and the outside of the mold 210 is required. The shape has a shape corresponding to the inner shape of the pump housing 100 in order to support the pump housing 100 so that the shape of the pump housing 100 does not change by the pressure of the melt injected. In addition, such a mold 210 can generally be easily manufactured and is not subject to any material.

As can be seen in FIG. 1, the pump housing 100 injected by the present invention has an internal shape of the pump housing 100, and thus the external pressure generated during the second injection only with the mold 210. It is difficult to support it.

Therefore, another additional device is needed to prevent the shape of the pump housing 100 from being deformed from the external pressure generated during the second injection.

In particular, it is difficult to manufacture the mold 210 to support the upper portion of the inlet 101, and since the inlet 101 is divided in the longitudinal direction, its shape is likely to be easily changed by external pressure. In order to secure this disadvantage, the secondary injection is inserted into the inside of the inlet 101 before the second injection, and the second injection is fixed after being fixed to support the inner upper surface of the inlet 101. .

The deflection prevention device 200 is rotatably coupled by a hinge 202 is a support 203 is fitted to the inlet of the inlet 101 and the support 200 for supporting the inner upper surface of the inlet 101. .

And the upper surface of the support 201 has a curved surface corresponding to the inner upper surface of the inlet 101, the length of the support 201 is the end of the support 201 is in contact with the upper side of the mold 210 It is long enough. The support 201 allows the entirety of the remaining portion of the flow path guide 104, which the mold 210 cannot support, to support the molten liquid generated during injection because the pump housing 100 is divided into two parts. This is to prevent shape deformation due to pressure.

In addition, the support 201 is coupled to the hinge 202 by the support 203 is fitted in the form of blocking the inlet of the inlet 101 is weak to prevent the deformation of the inlet, and also the support 201 It serves to fix the inlet 101 in close contact.

The sagging prevention device 200 having the above configuration has an upper sidewall of the mold 210 in which an end of the support 201 is inserted into the pump housing 100 when inserted into the inlet 101 for the second injection. The upper surface of the support 201 is in close contact with the inner upper surface of the inlet 101.

When the preparation is finished, the secondary injection is started on the pump housing 100, the secondary injection melt having a high pressure is permeated into the gap of the pump housing 100 coupled by the snap fit 105 Filling the space, the melt is fused to the surface of the pump housing 100 first injected by the high temperature.

If the mold 210 and the sag prevention device 200 are cooled after the second injection is completed and the pump housing 100 is cooled, all the injection processes are completed.

As described above, according to the present invention, in the first injection, a pair of pump housings which are divided so as to cross the inlet and the outlet vertically so as to be coupled by the snap pit is ejected and combined, and in the second injection, the sag is prevented from sagging. By inserting the device and then injecting it, it is possible to reduce the cost of manufacturing a mold having material properties with the proper melting point, and it is easy to manufacture the product without special technical know-how. It has the effect of reducing products that are not.

Claims (2)

In the injection method of the pump housing, A pair of snap feet 105 are formed on the upper side of the pair of pump housings 100, respectively, and a pair of pump housings 100 may be coupled to each other by the snap feet 105 at an edge contacting each other. A first injection step of injecting each half of the pump housing 100 in which the unevenness 103 is formed so as not to shift from each other along the edges in contact with each other; And The pump housing 100 is coupled by the respective female and male snap feet 105 formed at a position where the upper surface of the outlet port 102 and the upper surface of the inlet port 101 are in contact with each other, and the edges of the pump housing 100 facing each other close to each other. Mold supporting the inner side having a shape corresponding to the inner shape of the pump housing 100 in the lower portion of the pump housing 100 in a state that each pump housing 100 is not separated from each other by the irregularities 103 formed in the Inserting and fixing (210), the pump housing injection method comprising a second injection step of injecting again after inserting and fixing the deflection prevention device 200 to support to the inner upper surface of the inlet (101). The upper surface has a curved surface corresponding to the inner upper surface of the inlet 101 of the pump housing 100, the support 201 having a length such that the end end is in contact with the upper side of the mold 210; A fitting 203 which is fitted in a form of blocking the inlet of the inlet 101 to prevent deformation of the inlet, and also fixes the support 201 to be in close contact with the inlet 101; And It consists of a hinge 202 rotatably coupling the support 201 and the support 203 is inserted into the inlet 101 of the pump housing 100 before the second injection pump by the pressure generated during injection Deflection prevention device used for the injection of the pump housing 100 to prevent the shape of the housing 100 is deformed.